Control device for heat excange systems



July 31, 1945. w. HAND CONTROL DEVICE FOR HEAT EXCHANGE SYSTEMS Filed June 16, 1944 4 Sheets-Sheet l F I G. l

INVENTOR:

WILLIAM L. HAND,

ATTORNEY I w. L. HAND CONTROL DEVICE FOR HEAT EXCHANGE SYSTEMS 4 Sheets-Sheet 2 Filed June l6, 1944 a MM 4 %& a 4 a M Mm I K ,1 F 4 w e. I x F M m I 2 5 5 m f O M 6 9 4 I 0. w 4 v m 5 e W M 6 i 4 5 4 4 fm .M it: EEQEI 1 jam 5 Em 225m a: .5 v .I

3 Q T 4% a %g m INVENTOR: WILLIAM 1... HAND,

ATTORNEY July 31,1945. .w. L. HAND 2,380,839

CONTROL DEVICE FOR HEAT EXCHANGE SYSTEMS Filed June 16, 1944 4 Sheets-Sheet s m m 1 I, Y x. I M m W n W W F m w H mum 8 W 3 W. mfi Y l 6 7 Ya. I B 2. 1? A Y I cllrlllllllll 23 H L 1.-M e 1.1 w 4. l 11, 9 WHEIMUHFJu W Mm W .r M. 4 F 9 O 8 9 W 7 ATTORNEY July 31, 1945.v w

CONTROL DEVICE Eon HEAT EXCHANGE SYSTEMS- Filed June 16, 1944 4 Sheets-Sheet 4 3 a 4 I m 2 II/I/II/I/II/I/l/A WILLIAM L. HAND,

- ATTORNEY amount or fluid diverted Pat'ented July 3.1, 1945 UNITED STATES PATENT FFHQE CONTROL DEVICE FOR HEAT EXCHANG SYSTEMS William Louis Hand, Chicago, ill. Application June 16, 1944, Serial No. 540,707

- '1 Claims. (oi. res-37) This invention relates to flow control devices for fiuid' heat exchange systems. Such devices are for the purpose of balancing the operation of the system so that each section, branch, or unit of the system should take its proportionate share in the heat transfer. Since the proper distribution can be judged in terms of temperature, suchdevices can also be said to controlltemperature conditions in the branches of the system. While this includes heating as well as cooling systems,

the invention will be described, although; in no limiting sense, as being applied to hot water heating systems only.

More in particular, this, invention relates to control devices of the interceptor type inwhich a scoop-shaped interceptor member is employed to divert a portion of the flowin a main pipe into P separate branches oi. various locations from the a branch connection. That is to say, at a branch point an interceptor member projectspart way into the flow area inthe main pipe, and the depends upon the extent oi that projection.

fore adjustable, various drawbacks attach to them. Among such drawbacks is the fact that they requireor are embodied in special pipe fittings or couplings, which makes them awkward to install, inspect, exchange, or remove, since that cannot be done without disconnecting the pipes themselves from the fitting. Their application is subject to limitations or use in new piping systems and. cannot be used in existing piping systems without removing the greater part 01' the pipe lines and installing a new piping system."

It is among the objects or this invention to provide adjustable flow control devices 01' the interceptor type that are readily installable, removable, or inspectable, without necessitating the disconnection of the associated pipes themselves; to provide devices that will readily lend themselves to be installed in existing systems and even though the space conditions or limitations for the installation may vary widely at the various points or the-system, and irrespective of the presence or existing older control means of the valve type in the system; to provide devices that are substantially foolproof and non-binding or sticking, that are inexpensive, that are readily accessible for adjustment, and in which the degree oi! adjustment is accurate and visible by outward indicating means; and in which the inter-' source.

These .objects areattained by providing an interceptor member that is movable or adjustable along its longitudinal axis and into and out of the flow path in the main pipe. This includes the interceptor scoop itself and a stem unitary with the interceptor member and a stufling box-nipple provided and coaxial with a branch neck extending at right anglesi'rom the main pipe. The interceptor member is operatively supported in and guided by the stuffing boxnipple as well as longitudinally adjustable therein. The scoop member is arranged to be non-binding or -cloggingdue to the provision of certain clearance relationships between that member and the surrounding inner walls of associate pipe portions or fittings. The mounting of the interceptor device is such that it can be withdrawn and removed bodily from the branch neck whereupon otherwise disturbing the pipe connections. An

existing pipe system can thusbe easily converted to the use of the kind of interceptor device such as is herein proposed.

According to one feature, the intercepting scoop member itself consists of a tubular body portion terminating at one end in an elbow, lip, or scoop portion. The stem is rigidly and coaxially connected with the scoop member in a manner to leave a substantially free-flow passage therethrough. This member is shiitahle axially within a branch pipe connection and is thereby extendible or retractable at right angles with respect to the flow pathin the main pipe. The tubular body portion is allowed to move clear of the surrduuding inner walls or the branch pipe 1 connection from which or into which it leads. s0

its only operative and guiding support is derived from the stufilng box-nipple.

According to another feature thestufling boxnipple has associated with it means for the lon-' gitudinal fine adjustment of the interceptor member. More specifically, this is a diflerential screw fine adjustment comprising an annular differential screw member or fitting having inner and outer thread, its inner thread engaging the upper threaded end of the interceptor stennand its outer thread engaging an inner thread provided in the top portion of the stuffing box-nipple.

Other features relate to the iactthat the interceptor device is particularly well suited and adapted for installation or insertion in existing pipe systems. That is to say, one ieaturerprovides for an arrangement of fittings whereby the stem may be disposed to point co-directionally with the branch connection, while another feature allows for amounting in which the stem points in a direction opposite to that of the tain a desired flow distribution and desired temperature conditions in the branches of the system. This I' attain by combining the above defined manually operable interceptor device with automatic temperature responsivecontrol means capable of eflecting a setting of the intei'ceptor member in response to or in proportion to temperature changes occurring at a selected point of the system-and automatically r turning to the manual setting.

More specifically, an actuating device or head is mounted upon this stufling box-nipple to automatically effect the axial shifting of the the appended claims. The invention itself, however, both as to its organization and its method of operation, together with additional objects and advantages thereof, will best be understood from the following description of a specific em bodiment when read in connection with the accompanying drawings in which Figures 1, 2, 3, 4, 4, 5, 5', 5 show embodiments of the manually operated flow control device.

Figures 6, 6, 7, 8, 8 8 show embodiments of the automatically operated device, comprising actuating control means of the Sylphon-aquastat type.

The flow control device according to this invention is adaptable to a variety of local conditions or installation requirements such as may be encountered in existing pipe systems. There-- I out of the path of flow in a pipe.

interceptor stem. Temperature responsive transmitting means contacting the fluid medium in the pipe system lead to the control head to furnish the actuating impulse therefor. I

According to one feature, the control he comprises an annular impulse or force-transmitting member surrounding the upper end portion of the interceptor stem. That member may be in the form of an annular diaphragm construction or Sylphon bellows, or it may be in the shape of a solenoid coil, the movable core or plug for which is carried by and is coaxial with the interceptor stem.. The Sylphon bellows may tion, electric current for energizing the solenoid its crown portion l0 inltact represents an elongated or tubular body verse partition 22 t rtion 2| having a transh which extends the stem l4. Thus, there are formed in the stumng box housing member II an upper chamber or hollow 23 in which the adjusting nipple I 6 may be screwed up or down, and a lower chamber or hollow 2| filled with a packing or graphited sealing material 25 compressed by a stuiiing boxnipple or gland, member 28 in the form of a nipple or packing stem 21 having a square portion 21' may be received for example through a bi-metallic temperature controlled switch or through'a switch whichv is in turn controlled by aquastat conventional by themselves. .1

It'is possible to have the control head inthe nature of an optional attachment to the manually settable interceptor device as above defined.-

It is also possible to have a control head,"the component parts of which are alternatively mountable invariant ways. with the result that between its one end portion that is screwed into the chamber 24 and the other end portion that is screwed into the interior thread of a reducing nipple 28 the outer thread of which is screwed into the .neck 2! shown to be welded as at 2! into a mainpipe 3| in which the flow of the heat exchange fluid is indicated by an arrow 8!.

the impulse 'of the stern direction may be optionally utilized to produce a shift or the interceptor member in the one or in the other'direc-' The stufling box housing member 2| and the 'gland member 28' or stumng box-nipple 21 0011-: stitute together what is herein termed the stuffa is a branch pipe a welded, as at a mm the main pipe II. The scoop portion ll of theflow directing member ll lodges within the mam portion 01' the-branch pipe 8 there being provided {a wall clearance 84 between the scoop portion II and the surrounding interiorv surface '0! the -branchpipell. Inviewoithisclearancetheiiow component parts will be altered to reverse the sense of operation.

The novel features considered characteristic of my invention are setforth with particularity in directing member ll derives its sole support as well as longitudinal stabilization or guidance by nation of this stuffing box with such stem adjustingmeans as the adjusting nut It. The longitudinal r axial adjustment of the flow directing member ID may be effected with the aid of mechamcal but manually actuated adjusting means such as the nipple [6 or such adjusting means may be omitted and the stem l4 may be shifted by manipulating it directly as indicated in the embodiment in Figure 2.

In the construction shown in Figure l, the rotation by hand or by hand wrench of the adjusting nut or nipple I 6 while the stufiing box-nipple member remains stationary, will effect the axial shift of the stem I4 in the stufling box-nipple at a rate which depends upon the manner or ratio of threading as provided between the stem l4 and the nipple IS on the one hand, and be.- tween the nipple l6 and the stufiing box member on the other hand. Thus, by depending upon the kind and ratio of these two threads, there may be effected a ratio increasing or a ratio decreasingshifting movement of the stem M as a result of the rotation of the nipple l6. Such adjustment will move the scoop portion I I either into or out of the path of the fluid in the main pipe 30, and by shifting that portion far enough into the branch pipe 33, it may be fully removed from the flow area in the main pipe and thus rendered largely ineffective as a flow directing or flow intercepting means. v Yet, due to the wall clearance 34 between the scoop portion and the surrounding branch pipe a small flow therethrough of the fluid may still be allowed to continue between the main pipe and the branch pipe 33 with the result that this clearance is kept uncongested by solids or scales.

The Figure 1 example further indicates a mode of installing the device of this invention into or adopting it to an existing pipe system without the necessity of disturbing or disconnecting the existing main pipe on which the device is to be installed. Dot-and-dash lines 35 and 35 respectively indicate that portions of the main pipe 39 may be cut out to provide openings in the pipe wall which can then be built up into welded connections 29 and 33 respectively of the neck 29 and of the branch pipe 33 respectively with the main pipe 30.

Except for some structural variations the device in Figure 2 embodies the same basic princi-- ple of function as that in Figure 1, using a cap member or packing box nut 39 instead of the stuffing box member 29 of Figure 1 and allowing the free end of the stem M to protrude from that cap member. A flow directing member H3 otherwise is the same as the flow directingmember [0 in Figure 1. Gland member and stuffing born-nipple 26 21 and a reducing nipple 28 are the same as corresponding parts 26, 21 and 28 in Figure 1. However, the Figure 2 embodiment substitutes a pipe cross fitting 31 instead of the welded pipe connection shown in Figure l nd consequently shows threaded connections between that fitting and portions 38 and 39 of a main pipe, and threaded connections 31' and 31" with pipe portions 38 and 39 respectively, and a threaded connection 31 with a branch pipe 33 Another threaded connection 40 is between the neck 4| of the cross fitting 31 and the reducing nipple 28 Figure 1 can be built into threaded pipe fittings as shown in Figure 2 and Figure 2 can be built into welded branches as shown in Figure 1. The embodiment in Figure 3 takes care of installation requirements that are different from those that would constitute the environment of the embodiment of Figures 1 and 2. From a main pipe 44 extends a neck or branch connection 45 welded into the pipe asat 46. A T-pipe fitting 41 having a vertical body portion or straight portion 48 and a lateral branchor neck portion 49 is fastened by way of thread connection 50 upon the neck 45. A branch pipe 5| has a thread connection 52 with the fitting 41 by way of the neck portion 49 thereof. '11 longitudinally adjustable flow directing or fiow intercepting member 53 has ascoop portion 54 consisting of a tubular body portion 55 and a lip portion 56. A stem 51 is coaxial with the tubular body'portion 55 and fastened thereto in a manner more clearly shown in the detail Figures 4 5 and 5 The scoop portion 54 is shown to lodge in, and to be withdrawable into the neck 45 of the branch connection, while the stem 51 extends through the straight portion 49 of the fitting 41 and through the gland member or nipple 158 connected with the fitting 41 through a reducing nipple 59, and further extends through a stufling box member shown to be provided with stem adjusting means in the form of an adjusting nut or nipple 6|. Theparts 59, 58, 69 and El in Figure 3 correspond to similar parts 28, 21, 29, 16 in Fig. 1. Similarly, also, the stem 51 is non-rotatable although longitudinally shiftable in the gland member 58 because of a key and groove or spline connection 58 The scoop portion '54 can be rendered ineffective as a flow directing means by withdrawing it into the neck 45 of the branch connection, such withdrawn position being shown in dot and dash lines in Fig. 3. There is also noticeable in this figure as in Figure 1, a wall clearance 54 between the scoop portion 54 and the surrounding neck 45.

Figure 4 shows a T-pipe fitting 62 substituted for the welded connection 46 of Figure 3, and further shows a neck portion 63 having threaded connection 64 with the pipe fitting 62, and also showing main pipe portions 65 and 66 having threaded connections 61 and 68 with the pipe fitting 62.

Figure 5 illustrates an important feature inherent in the structural organization of this device, according to which the flow directing device including the flow directing axially shiftable member can be bodily lifted and withdrawn from its mounting on the main pipe without necessitating the disturbance or dismounting of any pipe connections. Referring to the Figure 3 embodiment, this means that neither the main pipe 44 nor the branch pipe 5! need be disturbed.

Figures 6 to 8 show embodiments of the control device with the addition of automatic actuating means therefor. They also indicate how the manually operated devices of Figures 1 to 5 can be converted to automatic operation, namely, by way of attachment of a control head for actuating the shiftable fiow directing member of the device. For this purpose, the control head may comprise a Sylphon (see Figures 6, 7) to act as the force-imparting member for the axial shifting of the flow directing member, the Sylphon in turn being operated through temperature responsive aquastat system.

Referring to Figure 6, the attachment of a control head H is effected by mounting it upon screwed into a reducing nipple 13 which in turn has threading engagement with a neck 14 shown to be welded as at 15 into a main pipe 16. Extending in a direction opposite to the neck 14 is a neck 11 having threaded connection with a branch pipe I8 in which lodges the scoop portion 19 having fixed thereto a stem 80 to constitute a longitudinally or axially shiftable flow directing member 8I. The scoop portion I9 comprises a tubular body portion 82 and a lip portion 83 to which the stem 80 is fixed so as to be coaxial with the tubular body portion 82. A clearance 84 is provided between the scoop portion I9 and the surrounding branch pipe 18. With the thread 85 provided at the free end portion of the stem 80, the flow directing member 8| itself is similar to the flow directing member I in Figure 1, or the flow directing member I0 in Figure 2, but its operative engagement with the control elements of the control head H is efiected through a nut 86 subject to the pressure of a spring 81 coiled around the stem 80 and confined between the nut 86 and the screw cap member 69. In addition, the control head H comprises an annular shaped Sylphon 88 through which extends the stem 80. The bottom 89 of the Sylphon is engaged by the nut 86, while the top 90 of the Sylphon engages a bracket 9| fastened by screws 92 to ,the inside of the top portion of an inverted housing shell 93 composed of two halves 93 and 93 (see also Fig. 8) and mounted on a base portion 94 by means of bayonet slot and screw connection 95 (see also detail Fig. 6

The base portion 94 has a downwardly extending neck 96 whereby it is fitted over the screw cap member 89 and fastened thereto as by a set screw 91.

The Sylphon 88 constitutes a part of a socalled aquastat system in that the interior of the Sylphon has a communicating tube connection 98 leading to an aquastat bulb 99 and forming therewith a closed system in which a temperature responsive fluid is confined. A temperature change affecting the bulb 99 will cause the fluid in the system to either expand or contract respectively as the case may be. Accordingly, the Sylphon 98 will either expand against the pressure of spring 81 and to the extent of that expansion shift the stem 80 downward and out of the path of the fluid in main pipe 16, or else the Sylphon will contract allowing the pressure of spring 81 to shift the stem 80 in the opposite direction, namely upward, thereby advancing the scoop portion I9 and more specifically the lip portion 83 thereof into the path of the liquid flowing through the main pipe I6. The bulb 99 contacts a heat exchange fluid in a pipe I00 which is part of the pipe system. The bulb is mounted on the pipe I00 through a neck IOI welded as at I02 on pipe I00 and a nipple or cap I03 engaging the neck.

A tubular portion I04 is fixed to and unitary with the nut 86 (see also Fig. 8 and surrounds the free end of the stem 80 and moreover extends through the Sylphon 88, the bracket 9!, as well as through the top of the housing shell 93. Thus a portion I05 of the tubular portion I04 is shown to be projecting upwardly from and out of the housing shell 93, the protruding portion serving as a means of manipulating and rotating the nut 86 manually from the outside in order to effect longitudinal positioning adjustment of the stem 80. In this way, one can adjust the range of shift of the flow directing member 8| to be effected by the automatic control head H relative to the flow area in the pipe 16.

Figure 7 shows the device of Figure 6 with certain parts drawn apart to illustrate the manner of attaching the control head H. In regard to this embodiment it shows how after loosening the set screw 91 the housing portion of the head, that is the base portion 94 and the shell portion 93 together with the Sylphon 88 can be slipped off the screw cap member 69, while the spring 81 and the nut 86 with its tubular portion I04 remain in place.

Figure 8 shows how the Figure 3 embodiment of the manually operated flow control device can be converted into an automatically operated unit. There is a main pipe I06 having a neck I01 welded thereto as at I08, a T-pipe fitting I09 has a body portion or straight portion H0 and a lateral neck portion III. At one end of the straight portion IIO this fitting has a threaded connection IIZ with the neck I97, and the neck portion III of the fitting has a threaded connection II 3 with a branch pipe H4. The opposite end of the straight portion II9 has a threaded connection II5 with a reducing nipple H6 into which is screwed a gland member or nipple II'I having key and groove or splined connection II8 with a stem II9 which is fixed to a scoop member I29, the stem H9 and the scoop member I28 constituting a flow directing member I2I that is longitudinally or axially'shiftable in the nipple Ill. The nipple II! has a packing of sealing material I22 confined in it by a sealing ring I23 and a closing cap member I24.

A control head H has a base portion I25 fitted over and fastened to the cap member I24 by means of a set screw I26. An inverted housing shell I 2'! is fastened to the base portion I25 by means of screws I28. A bracket I29 is mounted in the lower portion of the housing shell I21 by means of screws I30. An annular shaped Sylphon I3I rests upon the bracket surrounding the stern II9, the top I32 of the Sylphon engaging a nut I33 which in turn engages threads provided upon the outer end portion I34 of the stem II9. This nut I33 is under the pressure of a spring I35 confined between the nut I 33 and the top portion I36 of the housing shell I21. Fixed to and unitary with the nut I33 is a tubular portion I31 surrounding the extreme end portion of the stem H9 and in turn being surrounded by the coiled spring I35. The tubular portion I31 extends through and beyond the top portion I36 of the housing shell, thus presenting a protruding portion I38 whereby the nut I33 can be rotated on the stem I I9 for eifecting a longitudinal positioning adjustment of the flow directing member I2I. Thus one can adjust the range of operating movement of the flow directing member I2I relative to the flow area in the pipe I06, as it is to be eiTected by the operating head H. The Sylphon I3I has a communicating tube connection I39 with a bulb I40 with which it constitutes a temperature responsive so-called aquastat system in which a temperature responsive fluid is confined. The bulb I40 is affected by temperature changes of a fluid passing through a pipe MI, and it is mounted on the pipe I4I through a neck I42 welded thereto as at I43, and through a nipple or screw cap I44 havin thread connection with the neck I42.

Thus a rise in temperature of the fluid passing through pipe I4I will cause the Sylphon I3I to expand and accordingly to shift the stem II9 upwardly against the pressure of the spring I35.

A drop in temperature will cause contraction of the Sylphon and allow the stem I I9 to be shifted in the opposite direction by the pressure of the spring I35.

Comparing the embodiment of the Sylphon actuated type of Figure 6 and Figure 8 with one another, it will be noted that while each meets a different installation requirement in the pipe system, the control head H of Fig. 6 will assume the appearance of the control head H of Fig. 3

merely by a change in the mounting or by the reversal of parts within the control head. That is to say, the bracket 9| of Fig. 6 is reversed and mounted as in Figure 8 where it appears as 81 in Figure 6 disposed underneath the Sylphon 8B and within the lower portion of the housing shell appears in Figure 8 as spring I35 above the Sylphon I3I and Within the upper portion of the housing shell I21.

I claim:

1. In a heat exchange pipe system carrying heat exchange fluid and having a main fluid conveying pipe, a sleeve adapted for use as a branch to said pipe, a length of pipe telescoping witl'iin said sleeve and having one end open and its other end closed, said pipe having an opening in its side wall adjacent said closed end to form a scoop, said length of pipe having its one open end facing away from said main pipe, and means for moving said length oi pipe be tween two extreme positions, said pipe length having one extreme position where the scoop portion extends into the main pipe and faces the fluid stream for diverting fluid into said branch, said pipe length having another extreme position wherein said scoop portion is telescoped into said sleeve.

2. The structure of claim 1 wherein said pipe length and sleeve are so dimensioned as to provide a free annular space between the outside of said pipe length and opposed inside surface of said sleeve and wherein means are provided for supporting said pipe length in said sleeve to maintain said annular space.

3. The structure of claim 1 wherein said moving means includes a rod rigidly attached to said length of .pipe, said rod being disposed along the 4. The structure of claim 1 wherein said pipe length and sleeve are so dimensioned as to provide a free annular space between the outside of said pipe length and opposed inside surface of said sleeve and wherein said moving means comprises a rod rigidly attached to said length of pipe and extending longitudinally thereof, an elongated packing journal carried by said pipe system through which said rod passes from the interior of said pipe system to the exterior thereof, said journal being long enough so that said pipe length may be supported substantially symmetrically within said sleeve.

5. A valve for use in a heat exchange pipe system carrying heat exchange fluid, said valve comprising a branch to said fluid conveying pipe and a valve member disposed within said branch and movable axially of said branch, said valve member comprising a length of pipe having one end closed and the other end open and having an opening in its side wall adjacent the closed end to form a scoop, said length of pipe being disposed within said branch so that said open end faces away from the main fluid conveying pipe, means for moving said length axially of said branch from one extreme position where the scoop portion extends into said pipe to another extreme position wherein said scoop is telescoped into said branch, and means for restraining said movable pipe length against rotary movement with said scoop portion facing the normal fluid flow in said main pipe in its one extreme position.

6. A valve member for use in a heat exchange pipe system, said valve member comprising a length of pipe having one end open and the other end closed and having an opening in its side wall adjacent said other end to form a scoop and guide means attached to said pipe length adapted to impart longitudinal movement to said valve member while retaining the same locked against rotary movement.

'7. In a heat exchange pipe system carrying a heat exchange fluid and having a main fluid conveying pipe, a T section in said main pipe, the two alined ends of said T being in the main fluid stream, a length of pipe within said third T end, said length having one end open and the other end closed with the open end facing away from the T and said length of pipe having an opening in its side wall adjacent the closed end to form a scoop, means for moving said pipe length over a range having two extreme positions, one extreme position being where the scoop portion is in the T head in the main fluid stream and the other extreme position being where said scoop portion is telescoped into the third T end, and means for locking said pipe length against rotation in a position where the scoop portion faces the fluid stream when diverting fluid.

WILLIAM LOUIS HAND. 

